Dibucaine Mitigates Spreading Depolarization in Human Neocortical Slices and Prevents Acute Dendritic Injury in the Ischemic Rodent Neocortex

W. Christopher Risher; Mark R. Lee; Ioulia V. Fomitcheva; David C. Hess; Sergei A. Kirov

doi:10.1371/journal.pone.0022351

Abstract

Background

Spreading depolarizations that occur in patients with malignant stroke, subarachnoid/intracranial hemorrhage, and traumatic brain injury are known to facilitate neuronal damage in metabolically compromised brain tissue. The dramatic failure of brain ion homeostasis caused by propagating spreading depolarizations results in neuronal and astroglial swelling. In essence, swelling is the initial response and a sign of the acute neuronal injury that follows if energy deprivation is maintained. Choosing spreading depolarizations as a target for therapeutic intervention, we have used human brain slices and in vivo real-time two-photon laser scanning microscopy in the mouse neocortex to study potentially useful therapeutics against spreading depolarization-induced injury.

Methodology/Principal Findings

We have shown that anoxic or terminal depolarization, a spreading depolarization wave ignited in the ischemic core where neurons cannot repolarize, can be evoked in human slices from pediatric brains during simulated ischemia induced by oxygen/glucose deprivation or by exposure to ouabain. Changes in light transmittance (LT) tracked terminal depolarization in time and space. Though spreading depolarizations are notoriously difficult to block, terminal depolarization onset was delayed by dibucaine, a local amide anesthetic and sodium channel blocker. Remarkably, the occurrence of ouabain-induced terminal depolarization was delayed at a concentration of 1 µM that preserves synaptic function. Moreover, in vivo two-photon imaging in the penumbra revealed that, though spreading depolarizations did still occur, spreading depolarization-induced dendritic injury was inhibited by dibucaine administered intravenously at 2.5 mg/kg in a mouse stroke model.

Conclusions/Significance

Dibucaine mitigated the effects of spreading depolarization at a concentration that could be well-tolerated therapeutically. Hence, dibucaine is a promising candidate to protect the brain from ischemic injury with an approach that does not rely on the complete abolishment of spreading depolarizations.

Citation: Risher WC, Lee MR, Fomitcheva IV, Hess DC, Kirov SA (2011) Dibucaine Mitigates Spreading Depolarization in Human Neocortical Slices and Prevents Acute Dendritic Injury in the Ischemic Rodent Neocortex. PLoS ONE 6(7): e22351. https://doi.org/10.1371/journal.pone.0022351

Editor: Huaibin Cai, National Institute of Health, United States of America

Received: March 24, 2011; Accepted: June 20, 2011; Published: July 15, 2011

Copyright: © 2011 Risher et al. This is an open-access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.

Funding: This work was supported by National Institutes of Health Grants NS064753 (W.C.R.), NS057113 (S.A.K.), and NS062154 (S.A.K.). The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.

Competing interests: The authors have declared that no competing interests exist.

Introduction

Within minutes of focal stroke onset, a spreading depolarization originates from an area of severely decreased blood flow known as the ischemic core [1]–[4]. In the core, where neurons do not repolarize, this prolonged spreading depolarization is called the anoxic or terminal depolarization [4]. It propagates into the ischemic penumbra along a decreasing gradient of metabolic stress and into normoxic tissue where it becomes short-lasting [5]–[10]. Recurring spontaneous spreading depolarizations arising at the perimeter of the core propagate throughout the penumbra for hours to days in animal models and patients [11]–[17]. The prolonged duration of recurring spreading depolarizations further elevates metabolic stress in the penumbra due to the mismatch between energy supply and needs for recovery. Eventually penumbral neurons and astrocytes remain depolarized and overloaded with Ca²⁺, recruiting the tissue into infarct [11], [16], [18]–[20]. It has been proposed that a useful anti-stroke drug should abrogate spreading depolarizations without depressing normal synaptic function [4], [21]. We have recently shown that one such candidate is dibucaine, an FDA-approved local amide anesthetic and sodium channel blocker that potently inhibits terminal depolarization in rat brain slices while preserving synaptic function [22]. However, nearly all clinical trials of drugs that were effective in animal models of stroke/ischemia have failed, with the limited complexity of animal models compared to human stroke as well as fundamental differences between the brains of animals and humans assumed as contributing factors [23]. It is recognized by stroke experts that human brain slices are a crucial intermediate assay to forecast translational success before clinical trials [24]. Towards this end, we used light transmittance (LT) imaging to confirm that dibucaine diminishes the impact of terminal depolarization on live human neocortical slices prepared from pediatric brain tissue mostly resected for the treatment of intractable epilepsy as well as for neoplasm removal. We supplemented human slice experiments with a sophisticated in vivo approach using real-time 2-photon laser scanning microscopy (2PLSM) to show that spontaneous spreading depolarization-elicited dendritic damage is greatly reduced following photothrombosis-induced focal ischemia in dibucaine-treated mice. This success of dibucaine in reducing the negative effects of spreading depolarization makes it a strong candidate for further investigation to prevent spreading depolarization-induced neuronal damage in the acutely injured brain.

Materials and Methods

Ethics Statement

All protocols involving human tissue were approved by the Institutional Review Board at Georgia Health Sciences University. Written parents' informed consent documents and written children's assent documents were obtained prior to each study. All animal procedures were carried out in strict accordance with the recommendations in the Guide for the Care and Use of Laboratory Animals of the National Institutes of Health. The protocol for this study was specifically approved by the Animal Care and Use Committee at Georgia Health Sciences University (Permit Number 08-05-051). All surgery was performed under urethane anesthesia and all efforts were made to minimize animal discomfort and reduce the number of animals used.

Human Slice Preparation and Solutions

Human neocortical slices were made as previously described [25] from tissue resected from a total of 23 pediatric patients (average age∼9 y.o.) of both genders undergoing surgery for pharmacoresistant epilepsy (20 patients from whom tissue was used in the described experiments; these patients are listed in the Patient Table S1). Written parents' informed consent documents and written children's assent documents were obtained prior to each study. All protocols were approved by the Institutional Review Board at Georgia Health Sciences University. Coronal slices (400 µm) were cut using a vibrating-blade microtome (VT1000S, Leica Instruments) with ice-cold oxygenated sucrose-based artificial cerebrospinal fluid (Sucrose-ACSF) containing (in mM) 100 sucrose, 60 NaCl, 2.5 KCl, 26 NaHCO₃, 1.25 NaH₂PO₄, 1 CaCl₂, 5 MgCl₂, 10 glucose, pH 7.4, 290 mOsm/kg H₂O. Slices were transferred into an incubation chamber and maintained at room temperature for at least 1 hour in standard oxygenated ACSF containing (in mM) 125 NaCl, 2.5 KCl, 26 NaHCO₃, 1.25 NaH₂PO₄, 2 CaCl₂, 1 MgCl₂, 10 glucose, pH 7.4, 290 mOsm/kg H₂O. Some slices were transferred into a separate incubation chamber and pretreated for 1 hour at room temperature with ACSF containing 1 or 10 µM dibucaine hydrochloride (cinchocaine) [2-butoxy-N-(2-diethylaminoethyl) quinoline-4-carboxamide hydrochloride] or 0.1, 1, 5 or 100 µM minocycline. For imaging, a slice was transferred into a submersion-type imaging/recording chamber (RC-29, Warner Instruments) at 34°C and held down by an anchor (SHD-27LP/2, Warner). For oxygen/glucose deprivation (OGD, 20 min duration), ACSF was bubbled with 95%N₂–5%CO₂ and glucose lowered to 1 mM. NaCl was added to ACSF to osmotically balance the removed glucose. 100 µM ouabain was added to ACSF for chemical ischemia (15 min duration). Terminal depolarization induced by ouabain has been shown to elicit changes in LT, electrophysiology and drug effects indistinguishable from those seen following OGD-induced depolarization [21], [22], [26]. Therefore, we use the term ‘terminal depolarization’ for both OGD-induced depolarization and for the ouabain-induced depolarization. All chemicals were from Sigma Chemical unless indicated otherwise.

Intrinsic Optical Imaging

Intrinsic optical signals were acquired as previously described following standard protocols [22], [27], [28]. Slices were transilluminated with a broadband, halogen light source (Carl Zeiss) through a near-infrared pass filter. LT was collected with 2.5×/0.075NA air objective with dipping cone attachment [29] using the motorized upright Axioscope-2FS microscope (Zeiss) with IR-1000 CCD camera (Dage-MTI). Image frames were acquired at 30 Hz, digitized and averaged using a frame grabber controlled by Scion Imaging Software. Each image was generated by averaging 128 frames. The control image (T_cont) was subtracted from each subsequent experimental image (T_exp), resulting in an image series that revealed changes in LT over time [21], [22], [27], [28]. The LT change was expressed as the digital intensity of subtracted images (T_exp-T_cont) and displayed using a pseudocolor intensity scale. ‘Zones of interest’ were created in the images to quantify the data, with at least one zone positioned near the origin of the terminal depolarization front to record onset time. The difference (T_exp-T_cont) was normalized by dividing by T_cont which varies across the slice depending on the zone sampled. To accommodate for potential sample variables, we always compared control and drug-treated slices within tissue from the same patient.

Transgenic Mice

All animal procedures follow NIH guidelines and underwent yearly review by the Animal Care and Use Committee at Georgia Health Sciences University (Permit Number 08-05-051). All efforts were made to minimize animal discomfort and reduce the number of animals used. Founders of the B6.Cg-Tg(Thy1-EGFP)MJrs/J colony [GFP-M] were kindly provided by Dr. J. Sanes (Harvard University, Boston, MA). 12 GFP-M and 12 wild-type C57BL/6J male and female mice (average age∼4 months) were used in this study. Control data for in vivo experiments were taken from 24 GFP-M male and female mice (average age∼4 months) which were tested without drug treatment in a previous study [15] concurrently with the dibucaine-treated mice.

Mouse Slice Preparation and Electrophysiology

Acute murine slices (400 µm) were made from C57BL/6J mice according to standard protocols [30], [31]. Field excitatory postsynaptic potentials (fEPSPs) were recorded in the middle of stratum radiatum of hippocampal area CA1. Signals were recorded with MultiClamp 200B amplifier, filtered at 2 kHz, digitized at 10 kHz with Digidata 1322A interface board and analyzed with pClamp 9 software (Molecular Devices). Stimuli (100 µs duration) ranging from 10–200 µA were applied via small concentric bipolar electrode (25 µm pole separation; FHC). The slope function (mV/ms) of the fEPSP was measured from the steepest 400 µs segment of the negative field potential.

Preparation of Mice for In Vivo Imaging

Craniotomy for the optical window followed standard protocol [15]. Mice were anesthetized with an intraperitoneal injection of urethane (1.5 mg/g body weight) with heart rate monitored (450–650 beats/min) using MouseOx® pulse oximeter (STARR Life Sciences). Depth of anesthesia was assessed by toe pinch and heart rate monitoring, maintained with 10% of the initial urethane dose if necessary. Oxygen saturation level remained >90% for duration of experiments, indicating that mice were respiring properly under our imaging conditions. Hydration was maintained by intraperitoneal injection of 100 µl 0.9% NaCl with 20 mM glucose at 1 hour intervals. A 0.1 ml bolus of 5% (w/v) Texas Red Dextran (70 kDA) (Invitrogen) in 0.9% NaCl was injected into the tail vein for blood flow visualization. An optical chamber was constructed by covering the intact dura with a thin layer of 1.5% agarose prepared in a cortex buffer containing (in mM) 135 NaCl, 5.4 KCl, 1 MgCl₂, 1.8 CaCl₂, and 5 HEPES, pH 7.3. The optical chamber was left open to facilitate access with a glass microelectrode inserted through dura and used to record the cortical slow direct current (DC) potential with MultiClamp 200B amplifier at the site of imaged dendrites within layer I of somatosensory cortex. The Ag/AgCl pellet reference electrode (A-M Systems) was installed under the skin above the nasal bone. In a subset of mice, we assessed whether injection of a bolus of dibucaine hydrochloride into the tail vein (0.1 mL, 2.5 mg/kg, diluted in 0.9% NaCl) affects blood gas parameters. Mice were anesthetized with urethane (1.5 mg/g body weight) and one hundred microliters of blood were collected from a common carotid artery ∼1 h after dibucaine treatment and immediately quantified with a CG8+ blood gas cartridge and iStat1 blood gas analyzer (Abbott). Corresponding blood parameters were measured at ∼1 h in age- and sex-matched control mice that were anesthetized with urethane (1.5 mg/g body weight). Blood oxygen level and the acid–base balance were not statistically different in dibucaine-treated and control mice (t-test).

2PLSM

2PLSM images were collected with an IR-optimized 40×/0.8NA water immersion objective using the LSM 510 NLO META multiphoton system (Zeiss) mounted on the motorized upright Axioscope-2FS microscope. The scan module was directly coupled with the Spectra-Physics Ti:sapphire broadband mode-locked laser (Mai-Tai) tuned to 910 nm for 2-photon excitation. Three-dimensional time-lapse images were taken at 1 µm increments using 3× optical zoom, yielding a nominal spatial resolution of 6.86 pixels/µm (12 bits/pixel, 0.91 µs pixel time) across a 75×75 µm imaging field. Image Examiner (Zeiss) was used together with NIH ImageJ for image analysis. Dendritic beading was identified as the appearance of rounded regions extending beyond the diameter of the parent dendrite separated by “interbead” segments. Dendritic recovery was defined as the disappearance of rounded “beaded” regions.

Photothrombotic Stroke Model

Photothrombotic occlusion was implemented as described recently [15]. A bolus of Rose Bengal was injected through the tail vein (0.03 mg/g, diluted to 10 mg/ml in 0.9% NaCl). With LSM 510 software, the perimeter (100 µm wide) of a square-shaped region of interest (ROI, 1270×1270 µm) was irradiated with the 514 nm laser line through a 10×/0.3NA water immersion objective. The central square (1070×1070 µm) was not illuminated by the laser. Photothrombosis was stopped immediately upon occurrence of initial induced spreading depolarization recorded in the vicinity of imaged dendrites approximately in the center of the ROI. A bolus of dibucaine hydrochloride was injected into the tail vein (0.1 mL, 2.5 mg/kg, diluted in 0.9% NaCl) immediately after the onset of photothrombotically-induced spreading depolarization (or at 30 min after the onset of induced spreading depolarization in a subset of experiments).

Statistics

Statistica (StatSoft) was used to evaluate significant differences between conditions with two-way ANOVA. Two-tailed unpaired Student's t test, two-way repeated measures (RM) ANOVA, one-way ANOVA, one-way RM ANOVA and Chi-Square test were used when applicable. The significance criterion was p<0.05. Data are presented as mean±s.e.m.

Results

To test candidate neuroprotectants' ability to mitigate terminal depolarization in human tissue, we first confirmed that propagating terminal depolarization can be reliably generated in human neocortical slices from pediatric patients. A near-complete breakdown of the ion concentration gradients associated with propagating terminal depolarization causes dramatic neuronal and astroglial swelling, dendritic beading and spine loss within seconds, leading to acute cell death [7], [27], [31]–[33]. Terminal depolarization-induced swelling of neurons and glia results in increased tissue transparency, appearing as an elevated LT wave [22], [27], [28], [34], [35]. Terminal depolarization rapidly induces dendritic beading which scatters light, lowering LT in swollen tissue [22], [27], [36]. By imaging changes in LT we verified that terminal depolarization can be evoked in human slices exposed to OGD (Fig. 1A) or 100 µM ouabain (Fig. 2A, top row). A wave of elevated LT, signifying terminal depolarization, was elicited between 6–17 min during OGD (10.91±0.56 min; n = 27 slices) and between 5–10 min during exposure to ouabain (6.83±0.26 min; n = 22 slices). Terminal depolarization spread throughout gray matter at 2.31±0.42 mm/min. Terminal depolarization onset and speed of propagation were independent of patients' age and gender, as well as the cortical region of the resected tissue. Thus, neocortical slices from human pediatric brain tissue were viable and supported terminal depolarization.

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Figure 1. Global monitoring of terminal depolarization (TD) in human and mouse brain slices during dibucaine exposure.

A, A slice is transilluminated and transmitted light is collected by CCD camera to create the digital bright field image (left). Following OGD at 0 min, the gray matter displays a propagating wave of elevated LT (signifying terminal depolarization), represented by pseudocoloring according to changes in pixel values of the image (color scale: below, right). In this example, terminal depolarization is ignited within 13 minutes of OGD and spreads in all directions (arrows). Scale bar, 500 µm. B, fEPSPs recorded from CA1 of st. radiatum in mouse hippocampal slices are not noticeably affected by 1 hour of superfusion with ACSF containing 1 µM dibucaine. 10 µM dibucaine partially inhibited the evoked synaptic response, while 100 µM dibucaine completely abolished synaptic activity. Each row represents traces recorded from a single slice. C, Summary of synaptic responses during dibucaine exposure. Following 1 hour of control recording in standard ACSF, slices were superfused with ACSF containing 1 µM (left panel; n = 3 slices) or 10 µM dibucaine (right panel; n = 3 slices). At the end of 1 hour treatment with 1 µM dibucaine, ∼82% of the control fEPSP slope was preserved; 10 µM dibucaine reduced the fEPSP slope to ∼14% of control values (p<0.0001 for both; one-way ANOVA). D, Input/output graphs showing mean fEPSP slope at various stimulus intensities before and after 1 hour treatment with either 1 µM (left) or 10 µM (right) dibucaine (n = 3 slices for each concentration; *p<0.05, **p<0.001; two-way ANOVA).

https://doi.org/10.1371/journal.pone.0022351.g001

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Figure 2. Dibucaine pretreatment delays terminal depolarization in human neocortical slices.

A, Changes in LT (ΔLT) are utilized to track terminal depolarization in real time. The first image in each row shows bright field image of the slice. A control untreated slice incubated in standard ACSF (top row) undergoes terminal depolarization within 5 minutes of superfusion with 100 µM ouabain. Pseudocolored elevated ΔLT indicates cell swelling. In slices pretreated with either 1 or 10 µM dibucaine for 60 min (middle and bottom rows, respectively), ouabain-induced terminal depolarization is delayed by 2.1 and 4.8 min respectively and has less impact in terms of cell swelling. All three slices were from the same patient (#7; see Patient Table S1). Scale bar, 1 mm. B, Pretreatment for 1 hour with dibucaine significantly increases the latency to terminal depolarization onset induced by 100 µM ouabain or OGD when compared to untreated control slices from the same patient. C, Peak cell swelling during terminal depolarization in the same slices pretreated with dibucaine. The neuroprotective anti-inflammatory drug minocycline had no effect on terminal depolarization. Numbers of slices in each condition are indicated within each bar. Values are shown as percent of control (untreated slices from the same patient). Asterisks indicate significant differences from control (*p<0.05, **p<0.001, two-way ANOVA).

https://doi.org/10.1371/journal.pone.0022351.g002

We next investigated whether dibucaine can inhibit terminal depolarization in human slices. In control slices, terminal depolarization was induced by superfusion with ACSF containing the Na⁺/K⁺-ATPase inhibitor ouabain (Fig. 2A, top row; Video S1). Slices from the same patient were pretreated for 1 hour with either 1 or 10 µM dibucaine-containing ACSF, then ouabain was co-superfused with dibucaine-containing ACSF to induce terminal depolarization (Fig. 2A, middle and bottom rows respectively; Videos S2, S3). These concentrations were tested in mouse hippocampal slices for effects on evoked synaptic activity (Fig. 1B–D). Similar to our recent study in rat neocortical slices, 1 µM dibucaine largely preserved synaptic function [22]. The images in Fig. 2A show a noticeably subdued response to terminal depolarization in dibucaine-pretreated human slices. Quantification shows increased latency to terminal depolarization onset (Fig. 2B) induced by ouabain in 1 and 10 µM dibucaine-pretreated slices. Due to the limited availability of human tissue only 10 µM dibucaine was tested against OGD-induced terminal depolarization. At this concentration dibucaine was effective in significantly delaying the onset of OGD-induced terminal depolarization (Fig. 2B). Decreased peak LT during ouabain-induced terminal depolarization was significant only in slices treated with 1 µM dibucaine (Fig. 2C). By comparison, pretreatment for 1 hour with the neuroprotective antibiotic minocycline (0.1,1, 5 and 100 µM) [33] had no effect on the cellular response to terminal depolarization. In addition, ANOVA has shown that tissue response to dibucaine treatment was independent of gender and age of these pediatric patients (data not shown). We confirm that human brain slices represent a viable approach for screening candidate therapeutic drugs that target spreading depolarization, and that dibucaine is one such drug.

After observing dibucaine's ability to delay the onset of terminal depolarization in human brain slices and temper its effects in rodent slices (Douglas et al., 2011), we then wanted to see if its protective properties would extend to the ischemic penumbra in vivo by preventing injury to fine synaptic circuitry caused by recurrent waves of spontaneous depolarizations. We recently used a photothrombotic occlusion model [37] which employs the photosensitive dye Rose Bengal (RB) to create a focal ischemic lesion enclosing a penumbra-like “area at risk” in intact mice [15]. We used 2PLSM in the center of this area at risk to show that acute neuronal injury represented by dendritic beading was highly correlated with the occurrence of the initial spreading depolarization induced during RB photoactivation as well as with subsequent spontaneous spreading depolarizations (Fig. 3A). Nearly all spontaneous spreading depolarizations correlated with dendritic beading regardless of whether there was a nearby flowing blood vessel. This beading was typically reversible in the presence of nearby flowing blood vessels [15]. Here, dibucaine was administered immediately after the onset of photothrombotically-induced spreading depolarization. Though dibucaine did not inhibit the occurrence of spontaneous spreading depolarizations (12 spontaneous spreading depolarizations from 8 animals, compared to 35 spontaneous spreading depolarizations in 24 control animals), dendritic structure remained remarkably stable following recovery from initial induced spreading depolarization (Fig. 3B). Dibucaine significantly reduced the percentage of spontaneous spreading depolarizations that were temporally correlated with dendritic beading (Fig. 3C). When beading did occur during spontaneous spreading depolarization, bead density was decreased (Fig. 3D) though spine density was unaffected (Fig. 3E). Dibucaine's prevention of dendritic beading did not appear to be related to local perfusion since the frequency of observations of flowing versus non-flowing vessels near imaged dendrites did not change with recurring spontaneous spreading depolarizations (p = 0.7; Chi-Square Test). Intriguingly, in a subset of 4 mice in which dibucaine injection was delayed until 30 min after photothrombotically-induced initial spreading depolarization, no beading was seen following dibucaine administration. Additionally, dibucaine treatment did not affect the quantitative features of spontaneous spreading depolarizations (p>0.05, Mann–Whitney U test, data not shown), such as amplitude (potential difference between start of SD and the lowest point of the DC deflection), duration (time between the points corresponding to half the DC amplitude and the same potential during recovery), maximum rate of depolarization (taken from steepest 4 s segment of SD), and onset time (relative to time of initial induced SD onset and time since the previous SD). Nevertheless, dibucaine-treated mice had significantly fewer incidents of terminal dendritic beading (i.e. beading without further recovery), occurring in just 1 of 11 mice (compared to 13 of 17 control mice).

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Figure 3. Dibucaine lessens dendritic beading induced by spontaneous spreading depolarizations (SDs) in penumbra.

A, In vivo 2PLSM image sequence of dendrites (green) and a nearby flowing blood vessel (red; blood flow is indicated by stripes within vessel) from intact mouse somatosensory cortex. The images were taken from the center of the penumbra-like “area at risk”, surrounded by partially occluded blood vessels [15]. The dendrites bead (asterisks) during the initial spreading depolarization induced by cortical photothrombosis. The dendrites rapidly (<3 min) recover but become beaded again by the next spontaneous spreading depolarization even in the presence of a flowing blood vessel before recovering once more. Scale bar, 20 µm. B, Similar sequence to that shown in A, except dibucaine (2.5 mg/kg) was injected into the tail vein immediately after the onset of induced spreading depolarization. As in A, the dendrite rapidly recovers from beading (asterisks) induced by the initial spreading depolarization, but unlike the dendrites shown in A, the dendrite in the dibucaine-treated animal does not bead during a spontaneous spreading depolarization. Scale bar, 20 µm. C, Summary showing significantly decreased occurrence of dendritic beading (*p<0.05; Chi-Square Test) when dibucaine is administered i.v. immediately following onset of the initial spreading depolarization. D, Bead density during spontaneous spreading depolarizations is significantly decreased with dibucaine while E, spine density remains unaffected. Densities were assessed from random 30 µm segments of 3 dendrites in each imaging field as observed in maximum intensity projections of three-dimensional stacks in 5 control and 8 dibucaine treated mice. Data points (representing averages taken from individual dendrites) were only used when an image was taken near the peak of a recorded spreading depolarization. Values are shown as percentages of bead (D) or spine (E) density immediately after induced spreading depolarization (*p<0.05; two-way RM ANOVA).

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Discussion

We simulated ischemia in human neocortical slices to test the efficacy of candidate anti-stroke drugs in mitigating the effects of terminal depolarization. Ouabain-induced depolarization closely resembles terminal depolarization induced by OGD, and therefore both treatments are often used in rodent neuroprotective studies [21], [22], but rarely in human slices. Fundamental differences between rodent and human brain have long been considered as possible reasons why neuroprotective drugs that were effective in rodent models have failed in clinical stroke trials [23]. Energy failure during stroke is universal between species, but cerebral energy metabolism, blood flow and brain size vary. The human brain is larger and gyrated, reflecting increased size and number of neurons [7]. Phylogenetic changes are also reported, as human astrocytes are bigger, more complex and diverse [38]. Spreading depolarization under normoxic conditions can be elicited in human neocortical slices by potassium application, but the threshold is higher than in rat slices [39]. Human and rodent neocortical slices are different with respect to the latency of terminal depolarization onset induced by OGD (∼11 min human vs. ∼5.5 min rat slices [22]) or by ouabain (∼7 min human vs. ∼5 min rat slices [22]). Spreading depolarization cannot be triggered in the brains of newborn animals [7], but human neocortical slices obtained from even very young pediatric patents (∼2 y.o.) support terminal depolarization. We have therefore used an in vitro assay with human slices to test whether drugs shown to be effective in rodent models are also effective in human tissue.

Patient variables including age, gender, seizure etiology, resected cortical region, duration of the seizure disorder, age of onset, histopathological findings and history of medication may systematically affect tissue response. For those reasons, we always compared control and drug-treated experiments within tissue from the same patient and severely sclerotic tissue was excluded. The lack of “normal” tissue is a problem inherent to studies conducted on live human brain tissue in vitro, because obviously normal tissue cannot be removed. Nevertheless, testing candidate neuroprotectants in human brain slices was recognized in “The 2007 Feinberg lecture: a new road map for neuroprotection” as one crucial new step for developing novel therapies [24]. Epilepsy resections are the best source of differentiated viable human brain tissue available, and other investigators have used such tissue in similar studies [39], [40]. It is conceivable that the sensitivity of terminal depolarization to dibucaine in slices from the epileptic cortex may differ from normal cortex. “Non-epileptic” normal tissue is sometimes available, such as in the example shown in Fig. 2A where part of the occipital cortex was removed to access a benign tumor deeply located in the ventricle. This example is not different from our observations made in slices from epileptic cortex.

Terminal depolarization persistently resists pharmacological abrogation with blockers of voltage or ligand-gated ion channels [41], with the only successful attempts using a cocktail of glutamate receptor antagonists and voltage-dependent channel blockers [42], [43]. However, Yamada and co-authors [44] used rat hippocampal slices to show that 10 µM dibucaine prolonged the latency to OGD-induced terminal depolarization, decreased the maximal slope of this depolarization and induced partial recovery of neuronal membrane potential after reoxygenation/normoglycemia. Additionally, by measuring changes in LT and field potentials, Douglas and co-authors [22] reported that 1 µM dibucaine remarkably inhibits terminal depolarization in rat neocortical slices without altering synaptic function. Though dibucaine did not abolish terminal depolarization in human neocortical slices in our current studies, we observed that ouabain-induced terminal depolarization onset was delayed at the 1 µM concentration that preserved synaptic responses [22], indicating that this concentration could be well-tolerated therapeutically with minimal electrophysiological consequences. Terminal depolarization induced by OGD is more difficult to block than by ouabain [21], [22], perhaps because all energy requiring processes are inhibited by OGD, not just the Na⁺/K⁺-ATPase as in case of ouabain. OGD-induced terminal depolarization was delayed by 10 µM dibucaine in our experiments. Due to the limited availability of the human tissue, effectiveness of 1 µM dibucaine against OGD-induced terminal depolarizations was not tested in the current study, so future experiments (pending tissue availability) may be required to test lower concentrations of dibucaine against OGD-induced terminal depolarization. Furthermore, these findings from tissue resected from pediatric patients should ideally be compared to that from aged brains that are more at risk for stroke. Nevertheless our current study shows that dibucaine-like drugs could prove to be capable in protecting human brain from spreading depolarization-induced injury. It should be noted, though, that dibucaine is only approved for topical use by the FDA and may not be safe via an intravenous route. Its sister drug, lidocaine, is used to treat cardiac arrhythmias and its major side effects (e.g. CNS depression and convulsions) indicate that it crosses the blood brain barrier (BBB). Indeed, lidocaine was experimentally shown to be readily available for transport into the brain parenchyma across the BBB [45]. When lidocaine was injected i.v. in rabbits (4 mg/kg), it resulted in seizures with the cortical brain lidocaine level at 80±20 µg/ml and CSF lidocaine at 21±5 µg/ml [46]. Dibucaine injected i.v. can also cause seizures, as has been shown in animal models [47]. Additionally, accidental dibucaine overdose in pediatric patients results in seizures within minutes, indicating that it crosses the BBB [48].

Propagating terminal depolarization is difficult to spatially monitor in slices without complicated electrode arrays. Therefore, we used changes in LT to monitor this depolarization in time and space. In submerged slices, terminal depolarization-induced cellular swelling is the major source of increased LT [27], [28], [36]. Alternatively, direct imaging of dendritic injury and recovery with 2PLSM is a powerful approach to unambiguously monitor structural changes. Recently we have used 2PLSM imaging of single GFP-expressing neurons in mouse slices to demonstrate that dibucaine pretreatment was remarkably effective in reversing terminal depolarization-induced neuronal somata swelling and dendritic beading, with complete protection in some experiments [22]. Therefore, future 2PLSM experiments will be necessary to address the neuroprotective properties of dibucaine at the level of dendrites and dendritic spines in human slices.

Our study marks the first time that dibucaine-mediated protection of synaptic circuitry was confirmed in the penumbral zone in vivo. In the photothrombotic model, there is injury to the endothelium and microvasculature and early (within 15 minutes) breakdown of the BBB as evidenced by Evans blue leakage in the ring zone and some in the central penumbra [37]. Texas Red dextran (70 kDa) also leaks into the brain parenchyma after photothrombosis as assessed by signal detection outside capillaries [49], [50]. Perhaps the much lighter dibucaine (379.9 MW) can leak quickly under these conditions, thus providing protection for neurons and their dendrites. Because we administered dibucaine after the induction of photothrombosis, we were not able to assess the ability of dibucaine to delay the onset of the initial spreading depolarization as in our slice experiments. Instead, the critical findings of our in vivo experiments involved dibucaine's effect on spreading depolarization-induced dendritic beading. Terminal dendritic beading during ischemia is an early sign of acute injury leading to neuronal death [15], [51], [52]. Though the nonirradiated penumbra-like area at risk inside the lesion undergoes progressive hypoperfusion [15], penumbral dendrites have the ability to recover from spreading depolarization-induced beading, but this recovery is finite and depends on the presence of nearby flowing capillaries and thus the amount of energy available [15], [49], [50]. Remarkably, spreading depolarization-induced dendritic beading was significantly decreased following administration of dibucaine in intact mice subjected to focal photothrombotic occlusion. Importantly, terminal dendritic beading was observed only in one dibucaine-treated animal, suggesting that dibucaine-induced uncoupling of dendritic beading from the passage of recurrent spreading depolarizations protects dendrites by delaying terminal injury. Future studies using a different model where spreading depolarizations are frequently observed (e.g. middle cerebral artery occlusion) will be necessary to test whether infarct size is reduced by dibucaine.

The igniting mechanism of spreading depolarization during ischemia is of major interest, because drugs targeting spreading depolarization may protect the penumbra from progressively damaging depolarization waves [4], [21]. Sodium channel opening largely contributes to the depolarizing event although other channels are involved [7]. This may underlie the finding that sodium channel blockers are effective in delaying spreading depolarization but are not able to stop it once initiated [7], [53]. Thus, inhibition of terminal depolarization initiation by dibucaine likely involves an interaction with a sodium conductance because of its high binding affinity to the sodium channel [22]. Indeed, delaying the terminal depolarization onset should not be surprising for 10 µM dibucaine, because at this concentration dibucaine blocks enough sodium channels to inhibit action potentials and synaptic transmission. However, as revealed here and in our previous work [22] dibucaine inhibits terminal depolarization onset at 1 µM yet still preserves synaptic function. There are other reports where spreading depolarization was delayed by sodium channel blockers at concentrations that were too low to affect action potentials [54]–[56]. Remarkably, dibucaine (at 1 µM) displayed higher potency in inhibiting terminal depolarization onset in rodent slices than any other voltage-gated sodium channel blockers [22].

The mechanism by which dibucaine prevents dendritic beading despite the continued occurrence of spreading depolarizations is unclear. Spreading depolarization is characterized by severe disturbances of ion concentration gradients, resulting in the redistribution of ions across the membranes of metabolically compromised neurons [4], [7], [16]. Mammalian pyramidal neurons lack functional aquaporins, thus the molecular pathways by which they accumulate osmotically obligated water and swell during spreading depolarizations is uncertain [27]. Spreading depolarization possibly engages activation of a large conductance, such as pannexin-1 hemichannels [57], [58]. This should result in bulk water influx through the osmotically-tight neuronal compartment [27] leading to neuronal swelling and dendritic beading. It has been proposed that an interaction with such large ischemia-induced conductances would be neuroprotective [21] and may explain dibucaine's ability to prevent dendritic beading. Importantly, the success of experiments with dibucaine confirms that human brain slices are a suitable model system to identify and study potentially useful therapeutics targeting spreading depolarization. Furthermore, the protection of dendrites from the damaging effects of recurring spontaneous depolarizations is a surprising finding which suggests that a useful anti-stroke drug's therapeutic action may extend beyond mere inhibition of the spreading depolarization and that recording spreading depolarizations alone may not entirely reveal a drug's potential therapeutic benefit.

Supporting Information

Video S1.

Time series showing changes in LT evoked by 15 min of 100 µM ouabain exposure in a neocortical slice prepared from tissue obtained from a 7 y.o. female patient (patient # 7, see Patient Table S1). Time 0 corresponds to the beginning of ouabain exposure. A slice superfused with standard ACSF undergoes propagating terminal depolarization within ∼5 min of ouabain application. The terminal depolarization is imaged as an elevated LT (blue-yellow pseudocoloring signifying cell swelling).

https://doi.org/10.1371/journal.pone.0022351.s001

(MOV)

Video S2.

Similar time series to Video S1 of a slice from the same patient (patient #7) pretreated for 1 h with ACSF containing 1 µM dibucaine. Dibucaine incubation considerably delays the latency to the propagating terminal depolarization onset (6.8 min) and decreases peak cell swelling in the slice during co-superfusion with ACSF containing 100 µM ouabain and 1 µM dibucaine.

https://doi.org/10.1371/journal.pone.0022351.s002

(MOV)

Video S3.

Similar time series to Video S1 and S2 of a slice from the same patient (patient #7) pretreated for 1 h with ACSF containing 10 µM dibucaine. Dibucaine incubation considerably delays the latency to the propagating terminal depolarization onset (9.4 min) and decreases peak cell swelling in the slice during co-superfusion with ACSF containing 100 µM ouabain and 10 µM dibucaine.

https://doi.org/10.1371/journal.pone.0022351.s003

(MOV)

Table S1.

Patients in this study. Notes: FCD, focal cortical dysplasia [classification from: [59] Palmini A, Najm I, Avanzinin G et al. Terminology and classification of cortical dysplasias. Neurology 2004; 62 (suppl 3):S2–S8], DNT, Dysembryoplastic neuroepithelial tumour.

https://doi.org/10.1371/journal.pone.0022351.s004

(DOCX)

Acknowledgments

The authors thank Dr. David Andrew for helpful discussions throughout the conception and development of this project. We thank Ms. Deborah Croom and Dr. Jianghe Yuan for their excellent technical assistance.

Author Contributions

Conceived and designed the experiments: WCR DCH SAK. Performed the experiments: WCR SAK. Analyzed the data: WCR IVF SAK. Contributed reagents/materials/analysis tools: MRL. Wrote the paper: WCR SAK.

References

1. Leão AA (1947) Further observations on the spreading depression of activity in the cerebral cortex. J Neurophysiol 10: 409–414.
- View Article
- Google Scholar
2. Aitken PG, Tombaugh GC, Turner DA, Somjen GG (1998) Similar propagation of SD and hypoxic SD-like depolarization in rat hippocampus recorded optically and electrically. J Neurophysiol 80: 1514–1521.
- View Article
- Google Scholar
3. Farkas E, Bari F, Obrenovitch TP (2010) Multi-modal imaging of anoxic depolarization and hemodynamic changes induced by cardiac arrest in the rat cerebral cortex. Neuroimage 51: 734–742.
- View Article
- Google Scholar
4. Dreier JP (2011) The role of spreading depression, spreading depolarization and spreading ischemia in neurological disease. Nat Med 17: 439–447.
- View Article
- Google Scholar
5. Nedergaard M, Hansen AJ (1993) Characterization of cortical depolarizations evoked in focal cerebral ischemia. J Cereb Blood Flow Metab 13: 568–574.
- View Article
- Google Scholar
6. Busch E, Gyngell ML, Eis M, Hoehn-Berlage M, Hossmann KA (1996) Potassium-induced cortical spreading depressions during focal cerebral ischemia in rats: contribution to lesion growth assessed by diffusion-weighted NMR and biochemical imaging. J Cereb Blood Flow Metab 16: 1090–1099.
- View Article
- Google Scholar
7. Somjen GG (2004) Ions in the brain : normal function, seizures, and stroke. Oxford; New York: Oxford University Press.
8. Shin HK, Dunn AK, Jones PB, Boas DA, Moskowitz MA, et al. (2006) Vasoconstrictive neurovascular coupling during focal ischemic depolarizations. J Cereb Blood Flow Metab 26: 1018–1030.
- View Article
- Google Scholar
9. Strong AJ, Anderson PJ, Watts HR, Virley DJ, Lloyd A, et al. (2007) Peri-infarct depolarizations lead to loss of perfusion in ischaemic gyrencephalic cerebral cortex. Brain 130: 995–1008.
- View Article
- Google Scholar
10. Oliveira-Ferreira AI, Milakara D, Alam M, Jorks D, Major S, et al. (2010) Experimental and preliminary clinical evidence of an ischemic zone with prolonged negative DC shifts surrounded by a normally perfused tissue belt with persistent electrocorticographic depression. J Cereb Blood Flow Metab 30: 1504–1519.
- View Article
- Google Scholar
11. Hartings JA, Rolli ML, Lu XC, Tortella FC (2003) Delayed secondary phase of peri-infarct depolarizations after focal cerebral ischemia: relation to infarct growth and neuroprotection. J Neurosci 23: 11602–11610.
- View Article
- Google Scholar
12. Fabricius M, Fuhr S, Bhatia R, Boutelle M, Hashemi P, et al. (2006) Cortical spreading depression and peri-infarct depolarization in acutely injured human cerebral cortex. Brain 129: 778–790.
- View Article
- Google Scholar
13. Dohmen C, Sakowitz OW, Fabricius M, Bosche B, Reithmeier T, et al. (2008) Spreading depolarizations occur in human ischemic stroke with high incidence. Ann Neurol 63: 720–728.
- View Article
- Google Scholar
14. Nakamura H, Strong AJ, Dohmen C, Sakowitz OW, Vollmar S, et al. (2010) Spreading depolarizations cycle around and enlarge focal ischaemic brain lesions. Brain 133: 1994–2006.
- View Article
- Google Scholar
15. Risher WC, Ard D, Yuan J, Kirov SA (2010) Recurrent spontaneous spreading depolarizations facilitate acute dendritic injury in the ischemic penumbra. J Neurosci 30: 9859–9868.
- View Article
- Google Scholar
16. Lauritzen M, Dreier JP, Fabricius M, Hartings JA, Graf R, et al. (2011) Clinical relevance of cortical spreading depression in neurological disorders: migraine, malignant stroke, subarachnoid and intracranial hemorrhage, and traumatic brain injury. J Cereb Blood Flow Metab 31: 17–35.
- View Article
- Google Scholar
17. Mayevsky A, Doron A, Manor T, Meilin S, Zarchin N, et al. (1996) Cortical spreading depression recorded from the human brain using a multiparametric monitoring system. Brain Res 740: 268–274.
- View Article
- Google Scholar
18. Ohta K, Graf R, Rosner G, Heiss WD (2001) Calcium ion transients in peri-infarct depolarizations may deteriorate ion homeostasis and expand infarction in focal cerebral ischemia in cats. Stroke 32: 535–543.
- View Article
- Google Scholar
19. Dreier JP, Woitzik J, Fabricius M, Bhatia R, Major S, et al. (2006) Delayed ischaemic neurological deficits after subarachnoid haemorrhage are associated with clusters of spreading depolarizations. Brain 129: 3224–3237.
- View Article
- Google Scholar
20. Dietz RM, Weiss JH, Shuttleworth CW (2009) Contributions of Ca2+ and Zn2+ to spreading depression-like events and neuronal injury. J Neurochem 109: Suppl 1145–152.
- View Article
- Google Scholar
21. Anderson TR, Jarvis CR, Biedermann AJ, Molnar C, Andrew RD (2005) Blocking the anoxic depolarization protects without functional compromise following simulated stroke in cortical brain slices. J Neurophysiol 93: 963–979.
- View Article
- Google Scholar
22. Douglas HA, Callaway JK, Sword J, Kirov SA, Andrew RD (2011) Potent inhibition of anoxic depolarization by the sodium channel blocker dibucaine. J Neurophysiol 105: 1482–1494.
- View Article
- Google Scholar
23. Dirnagl U, Iadecola C, Moskowitz MA (1999) Pathobiology of ischaemic stroke: an integrated view. Trends Neurosci 22: 391–397.
- View Article
- Google Scholar
24. Donnan GA (2008) The 2007 Feinberg lecture: a new road map for neuroprotection. Stroke 39: 242.
- View Article
- Google Scholar
25. Witcher MR, Park YD, Lee MR, Sharma S, Harris KM, et al. (2010) Three-dimensional relationships between perisynaptic astroglia and human hippocampal synapses. Glia 58: 572–587.
- View Article
- Google Scholar
26. Jarvis CR, Anderson TR, Andrew RD (2001) Anoxic depolarization mediates acute damage independent of glutamate in neocortical brain slices. Cereb Cortex 11: 249–259.
- View Article
- Google Scholar
27. Andrew RD, Labron MW, Boehnke SE, Carnduff L, Kirov SA (2007) Physiological evidence that pyramidal neurons lack functional water channels. Cereb Cortex 17: 787–802.
- View Article
- Google Scholar
28. Davies ML, Kirov SA, Andrew RD (2007) Whole isolated neocortical and hippocampal preparations and their use in imaging studies. J Neurosci Methods 166: 203–216.
- View Article
- Google Scholar
29. Alexander JT, Nastuk WL (1975) Dipping cone to correct optical distortions at liquid surfaces. J Appl Physiol 39: 1041–1042.
- View Article
- Google Scholar
30. Kirov SA, Petrak LJ, Fiala JC, Harris KM (2004) Dendritic spines disappear with chilling but proliferate excessively upon rewarming of mature hippocampus. Neuroscience 127: 69–80.
- View Article
- Google Scholar
31. Risher WC, Andrew RD, Kirov SA (2009) Real-time passive volume responses of astrocytes to acute osmotic and ischemic stress in cortical slices and in vivo revealed by two-photon microscopy. Glia 57: 207–221.
- View Article
- Google Scholar
32. Basarsky TA, Duffy SN, Andrew RD, MacVicar BA (1998) Imaging spreading depression and associated intracellular calcium waves in brain slices. J Neurosci 18: 7189–7199.
- View Article
- Google Scholar
33. Obeidat AS, Andrew RD (1998) Spreading depression determines acute cellular damage in the hippocampal slice during oxygen/glucose deprivation. Eur J Neurosci 10: 3451–3461.
- View Article
- Google Scholar
34. MacVicar BA, Hochman D (1991) Imaging of synaptically evoked intrinsic optical signals in hippocampal slices. J Neurosci 11: 1458–1469.
- View Article
- Google Scholar
35. Zhou N, Gordon GR, Feighan D, MacVicar BA (2010) Transient swelling, acidification, and mitochondrial depolarization occurs in neurons but not astrocytes during spreading depression. Cereb Cortex 20: 2614–2624.
- View Article
- Google Scholar
36. Jarvis CR, Lilge L, Vipond GJ, Andrew RD (1999) Interpretation of intrinsic optical signals and calcein fluorescence during acute excitotoxic insult in the hippocampal slice. NeuroImage 10: 357–372.
- View Article
- Google Scholar
37. Wester P, Watson BD, Prado R, Dietrich WD (1995) A photothrombotic ‘ring’ model of rat stroke-in-evolution displaying putative penumbral inversion. Stroke 26: 444–450.
- View Article
- Google Scholar
38. Oberheim NA, Wang X, Goldman S, Nedergaard M (2006) Astrocytic complexity distinguishes the human brain. Trends Neurosci 29: 547–553.
- View Article
- Google Scholar
39. Petzold GC, Windmuller O, Haack S, Major S, Buchheim K, et al. (2005) Increased extracellular K+ concentration reduces the efficacy of N-methyl-D-aspartate receptor antagonists to block spreading depression-like depolarizations and spreading ischemia. Stroke 36: 1270–1277.
- View Article
- Google Scholar
40. Jiang C, Haddad GG (1992) Differential responses of neocortical neurons to glucose and/or O2 deprivation in the human and rat. J Neurophysiol 68: 2165–2173.
- View Article
- Google Scholar
41. Murphy TH, Li P, Betts K, Liu R (2008) Two-photon imaging of stroke onset in vivo reveals that NMDA-receptor independent ischemic depolarization is the major cause of rapid reversible damage to dendrites and spines. J Neurosci 28: 1756–1772.
- View Article
- Google Scholar
42. Muller M, Somjen GG (1998) Inhibition of major cationic inward currents prevents spreading depression-like hypoxic depolarization in rat hippocampal tissue slices. Brain Res 812: 1–13.
- View Article
- Google Scholar
43. Rossi DJ, Oshima T, Attwell D (2000) Glutamate release in severe brain ischaemia is mainly by reversed uptake. Nature 403: 316–321.
- View Article
- Google Scholar
44. Yamada A, Tanaka E, Niiyama S, Yamamoto S, Hamada M, et al. (2004) Protective actions of various local anesthetics against the membrane dysfunction produced by in vitro ischemia in rat hippocampal CA1 neurons. Neurosci Res 50: 291–298.
- View Article
- Google Scholar
45. Pardridge WM, Sakiyama R, Fierer G (1983) Transport of propranolol and lidocaine through the rat blood-brain barrier. Primary role of globulin-bound drug. J Clin Invest 71: 900–908.
- View Article
- Google Scholar
46. Momota Y, Artru AA, Powers KM, Mautz DS, Ueda Y (2000) Concentrations of lidocaine and monoethylglycine xylidide in brain, cerebrospinal fluid, and plasma during lidocaine-induced epileptiform electroencephalogram activity in rabbits: the effects of epinephrine and hypocapnia. Anesth Analg 91: 362–368.
- View Article
- Google Scholar
47. Shibata M, Shingu K, Murakawa M, Adachi T, Osawa M, et al. (1994) Tetraphasic actions of local anesthetics on central nervous system electrical activities in cats. Reg Anesth 19: 255–263.
- View Article
- Google Scholar
48. Dayan PS, Litovitz TL, Crouch BI, Scalzo AJ, Klein BL (1996) Fatal accidental dibucaine poisoning in children. Ann Emerg Med 28: 442–445.
- View Article
- Google Scholar
49. Zhang S, Boyd J, Delaney K, Murphy TH (2005) Rapid reversible changes in dendritic spine structure in vivo gated by the degree of ischemia. J Neurosci 25: 5333–5338.
- View Article
- Google Scholar
50. Zhang S, Murphy TH (2007) Imaging the impact of cortical microcirculation on synaptic structure and sensory-evoked hemodynamic responses in vivo. PLoS Biol 5: e119.
- View Article
- Google Scholar
51. Hori N, Carpenter DO (1994) Functional and morphological changes induced by transient in vivo ischemia. Exp Neurol 129: 279–289.
- View Article
- Google Scholar
52. Enright LE, Zhang S, Murphy TH (2007) Fine mapping of the spatial relationship between acute ischemia and dendritic structure indicates selective vulnerability of layer V neuron dendritic tufts within single neurons in vivo. J Cereb Blood Flow Metab 27: 1185–1200.
- View Article
- Google Scholar
53. Urenjak J, Obrenovitch TP (1996) Pharmacological modulation of voltage-gated Na+ channels: a rational and effective strategy against ischemic brain damage. Pharmacol Rev 48: 21–67.
- View Article
- Google Scholar
54. Weber ML, Taylor CP (1994) Damage from oxygen and glucose deprivation in hippocampal slices is prevented by tetrodotoxin, lidocaine and phenytoin without blockade of action potentials. Brain Res 664: 167–177.
- View Article
- Google Scholar
55. Taylor CP, Meldrum BS (1995) Na+ channels as targets for neuroprotective drugs. Trends Pharmacol Sci 16: 309–316.
- View Article
- Google Scholar
56. Fung ML, Croning MD, Haddad GG (1999) Sodium homeostasis in rat hippocampal slices during oxygen and glucose deprivation: role of voltage-sensitive sodium channels. Neurosci Lett 275: 41–44.
- View Article
- Google Scholar
57. Thompson RJ, Zhou N, MacVicar BA (2006) Ischemia opens neuronal gap junction hemichannels. Science 312: 924–927.
- View Article
- Google Scholar
58. Thompson RJ, Macvicar BA (2008) Connexin and pannexin hemichannels of neurons and astrocytes. Channels 2: 81–86.
- View Article
- Google Scholar
59. Palmini A, Najm I, Avanzini G, Babb T, Guerrini R, et al. (2004) Terminology and classification of the cortical dysplasias. Neurology 62: S2–8.
- View Article
- Google Scholar

[ref1] 1. Leão AA (1947) Further observations on the spreading depression of activity in the cerebral cortex. J Neurophysiol 10: 409–414.
View Article
Google Scholar

[2] View Article

[3] Google Scholar

[ref2] 2. Aitken PG, Tombaugh GC, Turner DA, Somjen GG (1998) Similar propagation of SD and hypoxic SD-like depolarization in rat hippocampus recorded optically and electrically. J Neurophysiol 80: 1514–1521.
View Article
Google Scholar

[5] View Article

[6] Google Scholar

[ref3] 3. Farkas E, Bari F, Obrenovitch TP (2010) Multi-modal imaging of anoxic depolarization and hemodynamic changes induced by cardiac arrest in the rat cerebral cortex. Neuroimage 51: 734–742.
View Article
Google Scholar

[8] View Article

[9] Google Scholar

[ref4] 4. Dreier JP (2011) The role of spreading depression, spreading depolarization and spreading ischemia in neurological disease. Nat Med 17: 439–447.
View Article
Google Scholar

[11] View Article

[12] Google Scholar

[ref5] 5. Nedergaard M, Hansen AJ (1993) Characterization of cortical depolarizations evoked in focal cerebral ischemia. J Cereb Blood Flow Metab 13: 568–574.
View Article
Google Scholar

[14] View Article

[15] Google Scholar

[ref6] 6. Busch E, Gyngell ML, Eis M, Hoehn-Berlage M, Hossmann KA (1996) Potassium-induced cortical spreading depressions during focal cerebral ischemia in rats: contribution to lesion growth assessed by diffusion-weighted NMR and biochemical imaging. J Cereb Blood Flow Metab 16: 1090–1099.
View Article
Google Scholar

[17] View Article

[18] Google Scholar

[ref7] 7. Somjen GG (2004) Ions in the brain : normal function, seizures, and stroke. Oxford; New York: Oxford University Press.

[ref8] 8. Shin HK, Dunn AK, Jones PB, Boas DA, Moskowitz MA, et al. (2006) Vasoconstrictive neurovascular coupling during focal ischemic depolarizations. J Cereb Blood Flow Metab 26: 1018–1030.
View Article
Google Scholar

[21] View Article

[22] Google Scholar

[ref9] 9. Strong AJ, Anderson PJ, Watts HR, Virley DJ, Lloyd A, et al. (2007) Peri-infarct depolarizations lead to loss of perfusion in ischaemic gyrencephalic cerebral cortex. Brain 130: 995–1008.
View Article
Google Scholar

[24] View Article

[25] Google Scholar

[ref10] 10. Oliveira-Ferreira AI, Milakara D, Alam M, Jorks D, Major S, et al. (2010) Experimental and preliminary clinical evidence of an ischemic zone with prolonged negative DC shifts surrounded by a normally perfused tissue belt with persistent electrocorticographic depression. J Cereb Blood Flow Metab 30: 1504–1519.
View Article
Google Scholar

[27] View Article

[28] Google Scholar

[ref11] 11. Hartings JA, Rolli ML, Lu XC, Tortella FC (2003) Delayed secondary phase of peri-infarct depolarizations after focal cerebral ischemia: relation to infarct growth and neuroprotection. J Neurosci 23: 11602–11610.
View Article
Google Scholar

[30] View Article

[31] Google Scholar

[ref12] 12. Fabricius M, Fuhr S, Bhatia R, Boutelle M, Hashemi P, et al. (2006) Cortical spreading depression and peri-infarct depolarization in acutely injured human cerebral cortex. Brain 129: 778–790.
View Article
Google Scholar

[33] View Article

[34] Google Scholar

[ref13] 13. Dohmen C, Sakowitz OW, Fabricius M, Bosche B, Reithmeier T, et al. (2008) Spreading depolarizations occur in human ischemic stroke with high incidence. Ann Neurol 63: 720–728.
View Article
Google Scholar

[36] View Article

[37] Google Scholar

[ref14] 14. Nakamura H, Strong AJ, Dohmen C, Sakowitz OW, Vollmar S, et al. (2010) Spreading depolarizations cycle around and enlarge focal ischaemic brain lesions. Brain 133: 1994–2006.
View Article
Google Scholar

[39] View Article

[40] Google Scholar

[ref15] 15. Risher WC, Ard D, Yuan J, Kirov SA (2010) Recurrent spontaneous spreading depolarizations facilitate acute dendritic injury in the ischemic penumbra. J Neurosci 30: 9859–9868.
View Article
Google Scholar

[42] View Article

[43] Google Scholar

[ref16] 16. Lauritzen M, Dreier JP, Fabricius M, Hartings JA, Graf R, et al. (2011) Clinical relevance of cortical spreading depression in neurological disorders: migraine, malignant stroke, subarachnoid and intracranial hemorrhage, and traumatic brain injury. J Cereb Blood Flow Metab 31: 17–35.
View Article
Google Scholar

[45] View Article

[46] Google Scholar

[ref17] 17. Mayevsky A, Doron A, Manor T, Meilin S, Zarchin N, et al. (1996) Cortical spreading depression recorded from the human brain using a multiparametric monitoring system. Brain Res 740: 268–274.
View Article
Google Scholar

[48] View Article

[49] Google Scholar

[ref18] 18. Ohta K, Graf R, Rosner G, Heiss WD (2001) Calcium ion transients in peri-infarct depolarizations may deteriorate ion homeostasis and expand infarction in focal cerebral ischemia in cats. Stroke 32: 535–543.
View Article
Google Scholar

[51] View Article

[52] Google Scholar

[ref19] 19. Dreier JP, Woitzik J, Fabricius M, Bhatia R, Major S, et al. (2006) Delayed ischaemic neurological deficits after subarachnoid haemorrhage are associated with clusters of spreading depolarizations. Brain 129: 3224–3237.
View Article
Google Scholar

[54] View Article

[55] Google Scholar

[ref20] 20. Dietz RM, Weiss JH, Shuttleworth CW (2009) Contributions of Ca2+ and Zn2+ to spreading depression-like events and neuronal injury. J Neurochem 109: Suppl 1145–152.
View Article
Google Scholar

[57] View Article

[58] Google Scholar

[ref21] 21. Anderson TR, Jarvis CR, Biedermann AJ, Molnar C, Andrew RD (2005) Blocking the anoxic depolarization protects without functional compromise following simulated stroke in cortical brain slices. J Neurophysiol 93: 963–979.
View Article
Google Scholar

[60] View Article

[61] Google Scholar

[ref22] 22. Douglas HA, Callaway JK, Sword J, Kirov SA, Andrew RD (2011) Potent inhibition of anoxic depolarization by the sodium channel blocker dibucaine. J Neurophysiol 105: 1482–1494.
View Article
Google Scholar

[63] View Article

[64] Google Scholar

[ref23] 23. Dirnagl U, Iadecola C, Moskowitz MA (1999) Pathobiology of ischaemic stroke: an integrated view. Trends Neurosci 22: 391–397.
View Article
Google Scholar

[66] View Article

[67] Google Scholar

[ref24] 24. Donnan GA (2008) The 2007 Feinberg lecture: a new road map for neuroprotection. Stroke 39: 242.
View Article
Google Scholar

[69] View Article

[70] Google Scholar

[ref25] 25. Witcher MR, Park YD, Lee MR, Sharma S, Harris KM, et al. (2010) Three-dimensional relationships between perisynaptic astroglia and human hippocampal synapses. Glia 58: 572–587.
View Article
Google Scholar

[72] View Article

[73] Google Scholar

[ref26] 26. Jarvis CR, Anderson TR, Andrew RD (2001) Anoxic depolarization mediates acute damage independent of glutamate in neocortical brain slices. Cereb Cortex 11: 249–259.
View Article
Google Scholar

[75] View Article

[76] Google Scholar

[ref27] 27. Andrew RD, Labron MW, Boehnke SE, Carnduff L, Kirov SA (2007) Physiological evidence that pyramidal neurons lack functional water channels. Cereb Cortex 17: 787–802.
View Article
Google Scholar

[78] View Article

[79] Google Scholar

[ref28] 28. Davies ML, Kirov SA, Andrew RD (2007) Whole isolated neocortical and hippocampal preparations and their use in imaging studies. J Neurosci Methods 166: 203–216.
View Article
Google Scholar

[81] View Article

[82] Google Scholar

[ref29] 29. Alexander JT, Nastuk WL (1975) Dipping cone to correct optical distortions at liquid surfaces. J Appl Physiol 39: 1041–1042.
View Article
Google Scholar

[84] View Article

[85] Google Scholar

[ref30] 30. Kirov SA, Petrak LJ, Fiala JC, Harris KM (2004) Dendritic spines disappear with chilling but proliferate excessively upon rewarming of mature hippocampus. Neuroscience 127: 69–80.
View Article
Google Scholar

[87] View Article

[88] Google Scholar

[ref31] 31. Risher WC, Andrew RD, Kirov SA (2009) Real-time passive volume responses of astrocytes to acute osmotic and ischemic stress in cortical slices and in vivo revealed by two-photon microscopy. Glia 57: 207–221.
View Article
Google Scholar

[90] View Article

[91] Google Scholar

[ref32] 32. Basarsky TA, Duffy SN, Andrew RD, MacVicar BA (1998) Imaging spreading depression and associated intracellular calcium waves in brain slices. J Neurosci 18: 7189–7199.
View Article
Google Scholar

[93] View Article

[94] Google Scholar

[ref33] 33. Obeidat AS, Andrew RD (1998) Spreading depression determines acute cellular damage in the hippocampal slice during oxygen/glucose deprivation. Eur J Neurosci 10: 3451–3461.
View Article
Google Scholar

[96] View Article

[97] Google Scholar

[ref34] 34. MacVicar BA, Hochman D (1991) Imaging of synaptically evoked intrinsic optical signals in hippocampal slices. J Neurosci 11: 1458–1469.
View Article
Google Scholar

[99] View Article

[100] Google Scholar

[ref35] 35. Zhou N, Gordon GR, Feighan D, MacVicar BA (2010) Transient swelling, acidification, and mitochondrial depolarization occurs in neurons but not astrocytes during spreading depression. Cereb Cortex 20: 2614–2624.
View Article
Google Scholar

[102] View Article

[103] Google Scholar

[ref36] 36. Jarvis CR, Lilge L, Vipond GJ, Andrew RD (1999) Interpretation of intrinsic optical signals and calcein fluorescence during acute excitotoxic insult in the hippocampal slice. NeuroImage 10: 357–372.
View Article
Google Scholar

[105] View Article

[106] Google Scholar

[ref37] 37. Wester P, Watson BD, Prado R, Dietrich WD (1995) A photothrombotic ‘ring’ model of rat stroke-in-evolution displaying putative penumbral inversion. Stroke 26: 444–450.
View Article
Google Scholar

[108] View Article

[109] Google Scholar

[ref38] 38. Oberheim NA, Wang X, Goldman S, Nedergaard M (2006) Astrocytic complexity distinguishes the human brain. Trends Neurosci 29: 547–553.
View Article
Google Scholar

[111] View Article

[112] Google Scholar

[ref39] 39. Petzold GC, Windmuller O, Haack S, Major S, Buchheim K, et al. (2005) Increased extracellular K+ concentration reduces the efficacy of N-methyl-D-aspartate receptor antagonists to block spreading depression-like depolarizations and spreading ischemia. Stroke 36: 1270–1277.
View Article
Google Scholar

[114] View Article

[115] Google Scholar

[ref40] 40. Jiang C, Haddad GG (1992) Differential responses of neocortical neurons to glucose and/or O2 deprivation in the human and rat. J Neurophysiol 68: 2165–2173.
View Article
Google Scholar

[117] View Article

[118] Google Scholar

[ref41] 41. Murphy TH, Li P, Betts K, Liu R (2008) Two-photon imaging of stroke onset in vivo reveals that NMDA-receptor independent ischemic depolarization is the major cause of rapid reversible damage to dendrites and spines. J Neurosci 28: 1756–1772.
View Article
Google Scholar

[120] View Article

[121] Google Scholar

[ref42] 42. Muller M, Somjen GG (1998) Inhibition of major cationic inward currents prevents spreading depression-like hypoxic depolarization in rat hippocampal tissue slices. Brain Res 812: 1–13.
View Article
Google Scholar

[123] View Article

[124] Google Scholar

[ref43] 43. Rossi DJ, Oshima T, Attwell D (2000) Glutamate release in severe brain ischaemia is mainly by reversed uptake. Nature 403: 316–321.
View Article
Google Scholar

[126] View Article

[127] Google Scholar

[ref44] 44. Yamada A, Tanaka E, Niiyama S, Yamamoto S, Hamada M, et al. (2004) Protective actions of various local anesthetics against the membrane dysfunction produced by in vitro ischemia in rat hippocampal CA1 neurons. Neurosci Res 50: 291–298.
View Article
Google Scholar

[129] View Article

[130] Google Scholar

[ref45] 45. Pardridge WM, Sakiyama R, Fierer G (1983) Transport of propranolol and lidocaine through the rat blood-brain barrier. Primary role of globulin-bound drug. J Clin Invest 71: 900–908.
View Article
Google Scholar

[132] View Article

[133] Google Scholar

[ref46] 46. Momota Y, Artru AA, Powers KM, Mautz DS, Ueda Y (2000) Concentrations of lidocaine and monoethylglycine xylidide in brain, cerebrospinal fluid, and plasma during lidocaine-induced epileptiform electroencephalogram activity in rabbits: the effects of epinephrine and hypocapnia. Anesth Analg 91: 362–368.
View Article
Google Scholar

[135] View Article

[136] Google Scholar

[ref47] 47. Shibata M, Shingu K, Murakawa M, Adachi T, Osawa M, et al. (1994) Tetraphasic actions of local anesthetics on central nervous system electrical activities in cats. Reg Anesth 19: 255–263.
View Article
Google Scholar

[138] View Article

[139] Google Scholar

[ref48] 48. Dayan PS, Litovitz TL, Crouch BI, Scalzo AJ, Klein BL (1996) Fatal accidental dibucaine poisoning in children. Ann Emerg Med 28: 442–445.
View Article
Google Scholar

[141] View Article

[142] Google Scholar

[ref49] 49. Zhang S, Boyd J, Delaney K, Murphy TH (2005) Rapid reversible changes in dendritic spine structure in vivo gated by the degree of ischemia. J Neurosci 25: 5333–5338.
View Article
Google Scholar

[144] View Article

[145] Google Scholar

[ref50] 50. Zhang S, Murphy TH (2007) Imaging the impact of cortical microcirculation on synaptic structure and sensory-evoked hemodynamic responses in vivo. PLoS Biol 5: e119.
View Article
Google Scholar

[147] View Article

[148] Google Scholar

[ref51] 51. Hori N, Carpenter DO (1994) Functional and morphological changes induced by transient in vivo ischemia. Exp Neurol 129: 279–289.
View Article
Google Scholar

[150] View Article

[151] Google Scholar

[ref52] 52. Enright LE, Zhang S, Murphy TH (2007) Fine mapping of the spatial relationship between acute ischemia and dendritic structure indicates selective vulnerability of layer V neuron dendritic tufts within single neurons in vivo. J Cereb Blood Flow Metab 27: 1185–1200.
View Article
Google Scholar

[153] View Article

[154] Google Scholar

[ref53] 53. Urenjak J, Obrenovitch TP (1996) Pharmacological modulation of voltage-gated Na+ channels: a rational and effective strategy against ischemic brain damage. Pharmacol Rev 48: 21–67.
View Article
Google Scholar

[156] View Article

[157] Google Scholar

[ref54] 54. Weber ML, Taylor CP (1994) Damage from oxygen and glucose deprivation in hippocampal slices is prevented by tetrodotoxin, lidocaine and phenytoin without blockade of action potentials. Brain Res 664: 167–177.
View Article
Google Scholar

[159] View Article

[160] Google Scholar

[ref55] 55. Taylor CP, Meldrum BS (1995) Na+ channels as targets for neuroprotective drugs. Trends Pharmacol Sci 16: 309–316.
View Article
Google Scholar

[162] View Article

[163] Google Scholar

[ref56] 56. Fung ML, Croning MD, Haddad GG (1999) Sodium homeostasis in rat hippocampal slices during oxygen and glucose deprivation: role of voltage-sensitive sodium channels. Neurosci Lett 275: 41–44.
View Article
Google Scholar

[165] View Article

[166] Google Scholar

[ref57] 57. Thompson RJ, Zhou N, MacVicar BA (2006) Ischemia opens neuronal gap junction hemichannels. Science 312: 924–927.
View Article
Google Scholar

[168] View Article

[169] Google Scholar

[ref58] 58. Thompson RJ, Macvicar BA (2008) Connexin and pannexin hemichannels of neurons and astrocytes. Channels 2: 81–86.
View Article
Google Scholar

[171] View Article

[172] Google Scholar

[ref59] 59. Palmini A, Najm I, Avanzini G, Babb T, Guerrini R, et al. (2004) Terminology and classification of the cortical dysplasias. Neurology 62: S2–8.
View Article
Google Scholar

[174] View Article

[175] Google Scholar

Figures

Abstract

Background

Methodology/Principal Findings

Conclusions/Significance

Introduction

Materials and Methods

Ethics Statement

Human Slice Preparation and Solutions

Intrinsic Optical Imaging

Transgenic Mice

Mouse Slice Preparation and Electrophysiology

Preparation of Mice for In Vivo Imaging

2PLSM

Photothrombotic Stroke Model

Statistics

Results

Discussion

Supporting Information

Video S1.

Video S2.

Video S3.

Table S1.

Acknowledgments

Author Contributions

References